Method and apparatus for lining blanks



March 28, 1950 H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS 14 Shets-Sheet 1 Filed March 17, 1948 lNVENTOR HELMER ANDERSON y M ATTORNEY March 28, 1950 H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 14 Sheets-Sheet 2 m 9 8' 12 [:1 m J 9 L-\ o \8 2 '2 8 a 3 3 g g m 5 (D Q a i 3 Q N a E 5 O" l a Q H a v o N o [I a I: Q 1

m N 5 2 3 N p INVENTOR HELMER ANDERSON BY a M March 28, 1950 H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 nmu INVENTOR I HELMER ANDERSON BY figlg M A TTORNE Y March 28, 1950 2,502,117

H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS 14 Sheets-Sheet 4 Filed March 1'7, 1948 INVENTOR HELMER ANDERSON BY QLZL'MCW A 7' TORNE Y March 28, 1950 Filed March 17, 1948 FIG. 5

14 Sheets-Sheet 5 lNVENTOR HELMER ANDERSON BY 7M1; 1 6M A TTORNE Y March 28, 1950 H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS l4 Sheets-Sheet 6 Filed'March 17, 1948 m2 mm we @2 9. \nn I" 6. 02 \)r E. 2. Q! 8 2: K m! an. s NM. mm2 m2 1 me E m m om NB on; 2 2: E. my I K m2 my 09 ll m: mm- 3: mg m. 5 Mn 2 2 9 'l E o! 02 mm. mm mm. 7 we 2: m2 w GE 5. .2

I INVENTOR HELMER ANDERSON BY W C, M

ATTORNEY H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS March 28, 1950 14 Sheets-Sheet 7 Filed March 17, 1948 INVENTOI? HELMER ANDERSON ATTORME Y March 28, 1950 H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS 14 Sheets-Sheet 8 Fild March 17, 1948 FIG.

FIG.

INVENTOR HELMER ANDERSON A TTORNEY March 28, 1950 H. ANDERSON 2,502,117

*' METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 14 She'ets-Sheet 9 FIG. I5

FIG. I?

E9 2 -LL INVENTOR HELMER ANDERSON Y 5) MC.

A TTORNE Y March 28, 1950 H. ANDERSON 2,502,117

METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 14 Sheets-Sheet 10 FIG. l8-

INVENTOR HELMER ANDERSON By 4M March 28, 1950 Filed March 17, 1948 if H. ANDERSON 2,502,117 METHOD AND APPARATUS FOR LINING BLANKS l4 Sheets-Sheet l1 FIG. 23

INVENTOR HELMER ANDER ON BY 9/,ZL'M

Match 28; 1950 H. ANDERSON METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 FIG. 25

FIG. 24

l4 Sheets-Sheet l2 HELMER v ANDERSON BY WJAMC. 5M

ATTORNEY March 28, 1950 H. ANDERSON 2,502,117

METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 I 14 Sheets-Sheet 1s lNVE/VTOR HELMER ANDERSON y C,

A T TORNE Y March 28, 1950 i H. ANDERSON 2,502,117

METHOD AND APPARATUS FOR LINING BLANKS Filed March 17, 1948 14 Sheets-Sheet 14 F I G. 27 525 526 FIG. 28 1!,

FIG. 30 v INVENTOR HELMER ANDERSON BY C".

A TTORNE Y Patented Mar. 28, 1950 UNITED STATES PATENT'OFFICE METHOD AND APPARATUS FOR LINING BLANKS Helmer Anderson, Minneapolis, Minn, assignor to General Mills, Inc., a corporation of Delaware Application March 17, 1948, Serial No. 15,375

This application relates to a method and apparatus for the manufacture of lined blanks and more particularly lined blanks of the type shown in the co-pending application of Clarence E. Felt and Lester F. Borchardt for Case liner, Serial No.

582,486 filed March 13, 1945, which is assigned to the same assignee as the present invention.

The blanks described and claimed in said copending application include a standard box blank provided with slots which separate the adjacent top and bottom flaps of the box. A lining is fastened to such a blank with portions of the lining overlapping the inner area of the flaps. It is desirable in such a case that the lining material be provided with slits corresponding to the slots in the blank so that the lining may be folded freely with the various flap portions.

It is accordingly one object of the present invention to provide an improved method and apparatus for the manufacture of lined blanks.

A further object is to provide a method of feeding blanks in spaced relation, applying a continuous strip of lining material to the series of spaced blanks, cutting the lining material between the blanks, and then slitting the lining material to correspond to the slots in the blanks.

Still another object is the provision of apparatus for carrying out the above method.

A further object is the provision of such an apparatus which has means to prevent the feeding of the blanks when the supply of lining material is interrupted combined with means to stop the feeding of the lining material whenever the supply of blanks is interrupted.

Still another object is to provide an improved slitting and. folding unit for such an apparatus.

Another object is the provision of an apparatus in which blanks are fed longitudinally and continuously in spaced relation. while a continuous strip of lining material is applied to the blanks and in which means are provided to out the" lining material between the blanks and then to move the blanks laterally and intermittently to a slitting station and a ioldingstation. A further object is the provision of improvedcombinations and control mean's'in such appa-' ratus. Other objects and advantages will be apparent from the following specification in which a pre ferred form of the invention has been described with particular reference to the accompanying drawings.

In the drawings, wherein like reference characters indicate like parts,

Fig. l is a perspective schematic viewwhich 20 Claims. (01. 93-3601) 2 illustrates the method and apparatus of the present invention.

Fig-2 is a side elevation of the feeding section, adhesive-applying section, and part of the lami-' nating section of such an apparatus, certain portions being broken away for clarity.

Fig. 3 is a similar side elevation showing the balance of the machine of Fig. 2.

Fig. 4 is a partial top plan of the final slitting and folding section of the machine of Figs. 2 and 3.

Fig. 5 is a partial schematic view of the feeding section of the machine.

Fig. 6 is a partial elevation of the adhesiveapplying section of the machine.

' Fig. '7 is a partial view of part of the control mechanism for the adhesive-applying section.

Fig. 8 is a partial sectional view of the machine taken on the line 8-8 of Fig. 2.

Fig. 9 is a sectional View on the line 9-9 of Fig. 3 with certain portions broken away for clearness.

Fig. 10 is a partial sectional view on the line Ill-l0 of Fig. 9.

Fig. 11 is an enlarged side view of a portion of the control means for the laminating section.

Fig. 12 is a view similar to Fig. 11 with the parts in a diiierent operative position.

Fig. 13 is a partial view similar to Figs. 11 and 12 with the parts in still another operating posi. tion.

Fig. 14 is an enlarged part al side elevation of the cutting section of the machine showing details of the control mechanism.

Fig. 15 is a view showing details of the cutting mechanism of Fig. 14.

Fig. 16 is a view similar to Fig. 15 but with the cutting knife in operative position with respect to the material being out.

Fig. 17 is a view of a brake device utilized in connection with the mechanism of Fig. 14.

Fig. 18 is a partial side view of the feeding and transfer mechanism which removes the blanks from" the cutting "section, taken from 'the opposite side of the machine from :the preceding figures;

Fig. 19 is a partial view o'f-the pushing mecha-' nism of-'Fig.18'. "I

Fig. 20 is'a partial top plan of the device of Fig. 18 illustrating details of the control mechanism. Fig. 21 is a partial sectional'view on the line atingmechanism for the slitting knives taken on the line 23-23 of Fig. 4,

Fig. 24 is an end view of a portion of the slitting mechanism taken from the lines 24-24 of Fig. 4.

Fig. 25 is a partial sectional view showing details of the clamping mechanism of the slitter, taken on the line 25-25 of Fig. 24.

Fig. 26 is a partial side elevation of the folding station takenonthe line 25-2fiof Fig. 4.

Fig. 27 is apartial end elevation of thefolding station taken on the line 2i2l of Fig. 26.

Fig. 28 is a schematic view illustrating the timing of the folding arms with the blank. in partially folded position.

Fig. 29 is a view similar to Fig. 28 with the blank completely folded.

Fig. 30 is a sectional view on the line fif -Bilof Fig. 27 illustrating the driving gears for the folding section, and

Fig. 31 is a View similar to Fig. 30 taken on the line 3l3l of Fig. 27.

The general nature of" the methodrandapparatus of the present invention is illustrated; in Fig. l of the drawing. As shown in thistfigure, theiblanks 35 which are tobe lined-are arran ed in a stack and are fed from one-end of. the stack, i. e., from the bottom-in a direction'perpendicular to the directionof the slots in-the blank. Each blank 35 includes score lines 36 which assist in. the ultimate-folding of the blank. The blank is a so provided with slots 3!- which divide the outer edges ofthe blank into top and bottom flaps 39; each of which, is attached. to one of the body sections 38 of the-blank.

The blanks are fed fromt'he stackrin spaced relation so that a lineof blanks travels continuously through the firstsectionsiof the machine with the blanks spaced a predetermined distance apart. A glue-applying roller H4 cooperates with a glue-feedineroller' I28 to apply stripes 4i of'aclhesive longitudina ly of'each blank.

A continuous'strip of lining material 42 fed from a supply spool 43 and'is laminated to-the blank by means of the adhesive stripes and' by cooperating laminating rolls, two of which, 2H and 288, are shown in Fig. 1. This lining material 42 is of a width which is greater than that f the body sections 38 of the blank so that the outer edges 32 of the lining overlap the top and bottom flaps 39 and a portion of the slots'3'l between such flaps.-

After the laminating operation, the lining material is severed between the b anks by, cooperat ing cutting members. 334and335. The point of severance is preferably shown immediately adjacent the forward edge of each blank so. that a flap 55:extends from the. trailing edge of each blank.

After the cuttingoperation, the lined blank with itstrailing flap is moved transversely of theoriginal line of feed to-a slittingstation where knives. i l? 911G453 slitthe lining; material to correspond-gto each of theslots 31 in thewblank and also slit the lining materialimmediately ad. jacent the trailing edgeof:the-: blan'k:

Finally, the lined and slit blanklisi sent to a folding station at whichifo'lding'. bars 525 and 52-! fold'the former leading and'trailingsections of the blank inwardly. in juxtaposedirelati'on where they may be taped or fastened? to form a partially assembled flat box blank.-v

In order to facilitate the description of the method and'apparatus accordingto the invention, the various sections and stations" of the device are discussed separately below.

Blank-feeding mechanism The mechanism for feeding the blanks 35 and for controlling the space between successive blanks is particularly shown in Figs. 2 and 5. The blanks 35 are fed one at a time from the bottom of a stack by means of a pair of feeding chains 5'? which carry lateral crossbars 48, the thickness of which is so adjusted that the bars 53 will engage only the bottom blank in the stack and will move that blank to the left in the figures toward the following sections of the machine.

In order to avoid interlocking engagement between the flaps of adjacent blanks, I prefer to utilize flap-deforming members 49, actuated in timed relation to the operation of feeding chains 41, as. described and claimed in my co-pending ap lication, Serial No. 4,013, filed January 23, 1948.

The feeding chains 4! are mounted at one end on idler. sprocketsv 50 fastened to. a shaft 5i car" ried inv adiustable bearings 52 on the frame of the machine. The other ends of the chains are carried by drive sprockets 53 which are rigidly carried by a shaft 54 likewise journaled in the main frame. A drive sprocket 55, fastened to shaft 5 5, is in turn driven by a chain 56. the other end of which passes over a sprocket Slon shaft 82. A. suitable idler sprocket 58 carried by an arm 59 pivotally mounted at 6! may be resiliently urged against chain 56 to maintain the proper tension on the feed chainand hold it in en agement with the respective sprock ts.

Shaft 62 is adaptedto be drivenintermittently by means of a one-revolution clutch. Such clutches are well. known in the art. Thus, a clutch arm Giiis fastened to shaft 62. At the outer end of this clutch arm 63 a driving pawl fill is pivoted as. at 65. Pawlifid has a lever arm 65 to which a-spring 61 is connected, the other end of said spring being fastened to an inner portionof arm 83. Thus the spring tends to rotate the pawl 64in a counter-clockwise direction in the figures so thatsaid pawl tends to engage the internal teeth 68 of a ring gear 69 driven at constant speed from an electric motor lb (Fig. 2) or other source of power by any desired connections (not shown).

A disengaging arm H. is also fastened to pawl member 64 and as the clutch arm 63 rotates in the direction of the arrow-in Fig. 5, this disengaging arm 7! will strike the end of a blocking lever '52 so that the pawl 54- will be rotated in a clockwise direction-against the action of spring iii to disengage the pawl from the gear teeth 68. Thus,- each time disengaging arm H strikes the blocking lever 12 the pawl will be disengaged from the teeth 68- of the driving gear and the clutch arm 53 and its shaft 62 will be stopped.

Blocking lever 72 is pivoted at 13 to a frame member and carries an actuating arm 14. A link 15 is pivotally. connectedtov the: arm M and to oneend of .alever .116 .which iisepivoteduat .l'l to. a suitable supporting .oriframe member." The otherv end 18 of lever...l6is.pivotally connected .to a link '89 whichin turn.is...pivoted tozthe core. 8! of a suitable solenoid 82. A spring 83 is fastened at one endto lever armJB andat the other end to'a frame member 84 and tends to pull the solenoid core downwardly and maintain the various levers in the position shown inv Fig. 5. The solenoid 82, on the other hand, tends to raise the end 18 of leverflewheneversaid solenoid is actuated and thereby rotates: blocking lever 12 out of the: pathof fdisengaginggjarmil I .1

In other words, whenever the solenoid 82 is not actuated, spring 83 will hold the parts in the position of Fig. 5 so that blocking lever I2 engages the throw-out arm II to disengage pawl 64 as the clutch arm 63 reaches the position of Fig. 5.

The solenoid 82 is actuated by electric current carried through wires 81 and 88. Wire 81 may be connected directly to one current supply line while wire 88 is connected to a suitable switch 89. The other terminal of switch 89 is in turn connected by a wire 99 to the other end of the electric supply line. Thus, whenever switch 89 is closed, the solenoid 82 will be actuated.

To actuate switch 89 a lever arm 92 is provided. Lever 92 is carried by a rotatable shaft 93 mounted in a frame member 94. A spring 95 tends to urge actuating arm 92 into engagement with the switch in order to close the switch and actuate solenoid 82. Lever 92 is further provided with a feeler arm 96, the outer end 91 of which is urged upwardly into the path of the blank 35 which is being fed. As long as a portion of the blank is passing over the end 91 of the feeler arm 96, the switch-actuating arm 92 will be held in the position of Fig. 5 with the switch open and the solenoid 82 unactuated.

However, as the end of each blank 35 passes beyond the end 91, the feeler arm 96 and actuating arm 92 are permitted to rotate slightly in a clockwise direction to actuate switch 89 and thereby activate the solenoid 82. Thus, the arm 96 and switch 89 will actuate the solenoid 82 just at the instant that the rear end of each blank 35 passes beyond the end 91 of the feeler. When the solenoid is actuated, its core BI will be pulled upwardly against the action of spring 33 so that blocking lever I2 is rotated in a counter-clockwise direction as described above, out of the path of throw-out arm II. The disengagement of the blocking lever I2 will thus permit spring 61 to rotate the pawl 64 into engagement with the teeth 68 of the constantly moving driving gear so that clutch arm 63 and shaft 62 will be driven with driving gear 69 for one complete revolution. This rotation of shaft 62 will cause one of the pushers 48 to feed another blank from the bottom 'of the stack and the forward edge of this blank will promptly engage the end 91 of the feeler arm 96 to depress said arm and open the switch 89. Thus, the solenoid 82 will be de-activated and spring 83 will return blocking lever I2 to the position of Fig. 5 where it will engage the throwout arm ll as the clutch arm 63 and shaft 62 comolete their first revolution. As successive blanks are fed, the cycle will be repeated.

It will be noted that the feeding chains 41 do not extend throughout the full length of the stack of blanks 35. In the device shown it is only necessary that the bottom blank be pushed far enough from the stack by means of chains 41 and pushers 48 so that the forward edge of said blank will pass between the feed rollers 98 and 99. These rollers are constantly driven and will serve to pull the blank the rest of the way from the stack after the pusher 48 has started the blank on its way and forced said blank into engagement with the feed rollers. These rollers 98 and 99 are mounted on shafts IDI and I92 respectively. An additional pair of feed rollers I93 and I04 are carried by shafts I95 and I06 respectively. The four shafts of these feed rollers may be interconnected as shown in Fig. 2. Thus, shafts II and I92 carryintermeshing gears I91 and I98 respectively. Similarly, shafts I05 and I06 are provided with interlocking gears I09 and III). An intermediate gear III carried by an idler shaft I I2 meshes with both of the gears I08 and I I9 so that all the feed roller shafts rotate together. One of these shafts, for example shaft I92, is connected to the source of power 10 by any desired means (not shown).

From the foregoing description of the feeding mechanism it will be apparent that the feed rollers 98, 99, I93, and I04 and the driving gear 99 will be driven constantly by the motor 70. The feeding chains 4'! with their pushers 48 will be actuated intermittently by means of the onerevolution clutch and the feeler or control arm 96 so that blanks will be fed successively from the bottom of the stack in spaced relation. By suitable adjustment of the various parts, any desired spacing between successive blanks may be achieved. The amount of spacing utilized for the present purpose is of the order of two inches, although this spacing may be changed without departure from the essential spirit of the invention.

Glue-applying mechanism After each blank 35 passes through the feeding rollers I93 and I94, it will next be moved beneath the glue-applying roller IE4 and between said roller and a cooperating feed roller II5. These rollers and their operating mechanism are shown in detail in Figs. 2, 6, and 7. The rollers are supported on driven shafts II 6 and I i! respectively. Shaft IE7 is mounted in fixed bearings in the main frame and may be connected in any suitable manner (not shown) to the driving motor I9 or to one of the power-actuated shafts such as shaft I66 of the feeding section.

As shown in Fig. l, the glue-applying roller H4 is not solid but consists of a series of spaced disks which are adapted to apply the glue or ad hesive in stripes 4| on the upper surface of each blank 35. Shaft II6, on which the glue-applying roller H4 is mounted, is journaled in the lower end of pivoted bearing arms II 8, one of which is positioned at each side of the machine. For convenience, only the bearings and supports at one side of the machine will be described. Bearing arms II8 are in turn pivoted at II9 to a movable supporting frame I2I. This frame I2I is pivoted at I22 to the main frame of the machine. The weight of the frame and of the roller and associated driving mechanism is so located with reference to pivot I22 that the roller II 4 is normally urged into contact with the top face of a blank 35 due to the action of gravity. Suitable stop means may be provided to prevent roller I I4 from dropping into actual contact with roller II5 when there is no blank in position. This stop means includes an adjustable stop screw I threaded into a projection I80 on the end of frame I 2!. The lower end of this screw engages the top of a horizontal stop plate I39 bolted to the main frame. Thus roller H4 will be held away from roller II5 a distance slightly less than the thickness of blanks so that roller II5 will not become coated with adhesive but will remain entirely clean.

The bearing arm H8 has an upward extension I23 through which an eye bolt I24 is loosely engaged. Thus, the end I 23 of bearing H8 is free to move longitudinally of the eye bolt I24. A stop or lock nut H5 at the outer end of the eye bolt I24 serves as a blocking means to limit the movement of the bearing arm to the right in Fig. 6. The other end of eye bolt I24 is rotatably other solenoid wire I69 may be connected to one side of switch III while the other side of the switch is connected by wire I12 to the other supply line.

A feeler arm I14 pivotally mounted at I15 to a suitable supporting bracket IIS on the frame is positioned to engage the strip 42 of lining material at a point between the supply spool 43 and the rollers of the laminating section. Normally the lining material 42 is under sufficient tension between these points so that it holds the feeler arm I in the heavy line position shown in Fig. 7. Should the lining material break, the arm I74 will drop to the dotted line position of Fig. '7. It will be noted that the lever arm I74 is integrally connected to a short switchactuating arm I'I'I which carries a cam roller I18. As the feeler I14 drops to the dotted line position, of Fig. 7 this roller I'I8 will engage the lower end of a switch-actuating lever I19 which is pivoted at I8I to a supporting bracket I82 fastened to the frame member I73. As the roller engages the lever I19 the latter will be forced to the right in the figure to actuate switch III and thus actuate the solenoid I61. The solenoid will then lift the glue-applying roller I I4 as described above so that no additional adhesive will be-applied to the blanks until the supply of lining material 42 is repaired or replenished.

In order to avoid feeding additional blanks 35 through the glue section to the laminating section while the supply of lining material 42 is interrupted, an additional switch mechanism has been provided as shown in Fig. 6. Thus a switch actuator arm IE3 is fastened to shaft Hi3 so that it moves downwardly whenever the solenoid is actuated to lift the glue-applying roller. This arm I83 includes a switch actuating button I84 which may be threaded into the end of the arm so that its position may be adjusted accurately. The button I84 in turn engages the actuator I85 of a master switch I 86 which is connected by wires I81 and I80 to the main driving motor 70 in such a Way that actuation of switch I86 by arm I83 will stop the motor. Thus, not only is the glue-applying roller lifted when the supply of lining material 42 is interrupted, but also the driving motor for the remainder of the machine is stopped so that additional blanks will not be fed into the gluing section or to the laminating section. Furthermore, as indicated above, the rollers of the gluing section are driven from a separate source of power so that they will continue to rotate and prevent drying of the adhesive even though the balance of the machine has been stopped.

Laminating mechanism After the blanks 35 have passed through the adhesive-applying section of the machine, they are next fed toward the laminating section. A group of four cooperating feed rollers is utilized to feed the blanks to a control device after which the lining material is laminated to said blanks. These preliminary feed rollers of the laminating section are in pairs similar to those shown in Fig.-

8' which shows the first pair of rollers consisting ofan upper roller I90 and a lower roller ISI.

These rollers are carried on shafts I92 and I93 respectively. The bottom feed roller I9I is an ordinary smooth roll, while the upper roller I90 consists of a number of separated narrow rolls which are adapted to engage the blank 35 at points between the longitudinal stripes of adhesive 4|. Obviously, a solid upper roll would smear the adhesive and would soon become coated with particles of the adhesive. This difficulty is avoided by use of the separate narrow rolls as shown. A similar pair of feed rollers is carried on shafts I94 and I95 respectively. To connect these four rollers in driving relation, gears may be employed similar to those utilized for the initial feed rolls 98,99, I03, and I94.

Thus intermeshing gears I96 and E9! on shafts I92 and I93 respectively serve to connect these shafts in driving relation to each other while similar gears I98 and I99 mesh with each other to connect the respective shafts I 94 and I95. An intermediate gear Eel journaled in the frame 202 meshes with both the gears I97 and I99 so that all four of the feed roll shafts rotate together in the same direction.

To drive these shafts a sprocket 203 is provided on shaft I95. This sprocket is driven through a chain 204 from a driving sprocket 205 on auxiliary driving shaft 206. The customary idler sprocket 2H journaled on an arm 2I2 pivoted to the frame at 2I3 is resiliently urged against chain 204 to take up any slack in saidchain.

Auxiliary drive shaft 206 in turn carries a sprocket 20'! which is driven by a chain 208 from a sprocket (not shown) on main drive shaft 209 (Fig. 3.) Shaft 209 is in turn connected to the driving motor I0 by any suitable means such as, for example, sprockets and chains (not shown).

As the blanks 35 leave the gluing section, they will be moved by the feed rollers just described so that they pass beneath a guide 2 I4 and over a control mechanism designated generally as 2I5, after which said blanks pass through the laminating rollers 2II and 2I8 which press the lining material 42 firmly against the upper surface of the blanks. This lining material 42 passes to the laminating rolls 2I'I and 2I8 over guide rolls 22I and 2IB (Fig. 2) from a supply spool 43. There are three pairs of cooperating rolls in the laminating section which press the lining material 42 firmly against the blanks 35 so that the adhesive stripes 4| may form a firm bond between the two. The first two of these laminating rollers 2H and 2I8 are carried on shafts 2 I9 and 220 re-' spectively. Similar shafts 222 and 223 carry the next pair of laminating rolls 224 and 225 (see Fig. 9). Intermeshing gears on the respective upper and lower rolls serve to connect the rolls for rotation in opposite directions to feed and press the blanks. The intermeshing gears are similar to those previously described in connection with feed rolls 9B, 99, I03, and I04 and also the feed rolls 2I'I and2l8. Two of these gears are shown in Fig. 9, gear 226 being on the upper shaft 222 and gear 22! on the lower shaft 223 of the second pair of laminating rolls. These gears are similar to those described for the other feed rolls except that they are located on the opposite side of the machine. Similar gears on the first pair of laminating rolls 2I'I and. 2I8 may be interconnected with gears 226 and 221 by an intermediate idler gear (not shown) journaled on a shaft 228 (-Fig. 2).

The third and final pair of laminating rolls 229 and 23I are carried on shafts 232 and 233 respectively. Intermeshing gears of the type just described connect said rolls to each other, and the lower shaft 233 may be connected to shaft 223 by a chain and sprockets (not shown). It is contemplated that shaft 223 will be driven from one of the power shafts by a further sprocket and chain (not shown).

Theupper shafts 219., .222, and 232 of the laminating section are journaled in bearings 23 which are vertically movable in the side frames 222 (see Fig. 9). A lifting rod 235 is attached to each bearing 232. Mechanism is provided to lift these rods and bearings and thereby lift the upper laminating rollers away from the lower rollers so that no feeding movement will be imparted to the laminating material 42 in the event that the supply of blanks 35 is interrupted for any reason. This mechanism is shown in Figs. 9 and 10. By reason of this safety mechanism, any waste of the laminating material due to the feeding of such material by the laminating rollers, when no blank 35 is in position between the rollers, will be avoided.

Lifting rods 235 are threaded at their upper ends 235 and adjusting nuts 231 are fastened to the threaded ends. The lower side of each adjusting nut is engaged by a lifting fork or lever 239 fastened to a shaft 239 which extends longitudinall of the machine. A similar shaft 241 at the other side of the machine carries similar lifting levers 238 for the lifting rods 235 and bearings 233 on that side of the machine. The two lifting shafts 239 and 2d! are interconnected for simultaneous rotation in opposite directions as shown in Fig. 9 so that the bearings 234 at each side of the machine will be lifted simultaneously to maintain the upper shafts 212, 222, and 232 horizontal as they are lifted. Thus, a downwardly extending lever arm 222 on shaft 239 is connected to an upwardly directed lever arm 243 on shaft 24! by a connecting rod 242 which is pivoted at 245 to lever 242 and at 226 to lever 243. The central portion 241 of connecting rod 244 may be of turnbuckle construction for adjustment of the parts. A connecting link 2 18 is pivoted at 2 39 to the crank arm 242 toactuate said arm and thereby actuate shafts 239 and 24! to lift the bearing 234. This link 248 is pivoted at its other end 256 to a two-arm lever 251,, the center of which is pivoted at 252 to the main frame. The lower end of lever 25! is pivotally connected at 253 to a further connecting rod 254 which extends laterally across the machine and is pivoted at its other end 265 to the upper end of a cam lever 256. A turnbuckle construction 25-! on connecting rod 252 permits of adjustment of this portion of the drive mechanism.

Cam lever 26.6 is "pivoted at 259 to one of the frame members and carries at its lower end a cam roller .259. This roller engages the flat surface 268 of a cam disc 26! fastened to driven shaft 262. A raised portion 263 on the face of the cam disc is adapted to engage the cam roller 259 when the disc 261 is rotated and move said cam roller to the right in Fig. 9. This movement will be transmitted through the linkage just described to rotate shafts 239 and 22! in a counter-clockwise direction so as to lift the bearings 234.

.-Shaft 222 maybe driven from a constantly rotating :dr ive'gear 26 1 by means of a one-revolution clutch member 265. Driving gear 262 is inturn connected to the main driving mechanism of the machine through a sprocket 266 and chain.

The one-revolution clutch is similar to that described in connection ith the feeding section of the machine and is shown in detail in Fig. 10. Thus, the clutch member 265 is provided with a drive pawl 261 pivoted to the member 265 at 268. Pawl 261 is adapted to engage the teeth of the driving gear 264 whenever' the clutch is operated. A disengaging arm 269 is connected to the pawl 261 and is adapted tostrike a blocking lever 21! which holds the pawl 261 out of engagement with gear 264 against the action of spring 212. Whenever the blocking lever 21| is moved downwardly out of the path of disengaging arm 269, the spring 212 will rotate the pawl 26? into engagement with the gear 292 so that the clutch member 265 will be driven by the gear and will rotate with it until disengaging arm 269 again strikes the blocking lever 21L Lever 216 is carried by a shaft 212 pivoted to the frame of the machine. The lever and shaft turn as a unit. A crank arm 213 is integrally connected to the shaft 216 and is urged in a counter-clockwise direction by a spring 214 fastened to a frame bracket 215. Shaft 216 likewise carries a stop arm 216 which is urged against the stop screw 211 in the frame by the action of spring 214. In this position blocking lever 21! is in position to intercept the disengaging arm 269 of pawl 261.

Atr'ipping arm 21.3 is likewise connected to shaft 215} and is positioned in the path of a tripping pawl 219 pivoted at 281 to a crank arm 232. Crank .282 in turn is pivoted at 263 to a frame bracket 284.

Pawl 219 is urged in a clockwise direction against a stop 286 by spring 285. In this position the pawl will engage the tripping arm 212 and raise said arm whenever the crank 232 is lifted. Such engagement will rotate shaft 212 to move the blocking .lever 21! out of the path of the clutch arm 269.

In order to lift the crank 282 said crank arm is connected by a link 281 to the core 288 of a solenoid 289. Wires 29l and 292 carry current to the solenoid and are con nected in circuit with a suitable control device to be described. Thus whenever the solenoid is energized the crank 282 will be raised and tripping pawl 219 will engage and move the tripping arm 218. When the solenoid is de-energized, its core 288 and crank arm 282 will drop. During the downward movement of arm 282, the tripping pawl 219 will engage the top of lever 218 and will be rotated counter-clockwise against the resilience of spring 285 to permit the pawl to pass arm 218 and resume its initial position below said arm.

By reason of the mechanism just described, actuation of solenoid 229 will trip the one-revolution clutch to cause rotation of cam 26L This in turn will rotate shafts 239 and 24! to lift the upper bearings 234 and their shafts and rollers. To retain the hearings in their upper position a latch arm 293 is provided on shaft 239. The lower end 2920f this arm 293 normally rides on the top 295 of oneend of a latch member 296. Member 226 is pivoted at 291 to the frame and is connected at its other end 298 by means of a link 299 to the core 362 of 'a solenoid 363. The usual pivotal connection 361 is provided between link 299 and core 322. Wires 36d and 365 are also conected to the control device 2 IE to actuate the solenoid when desired. As long as the solenoid is de-energized its core 362 will tend to drop under the action of gravity so that the end 295 of latch 226 will be urged in an upward direction. Thus, --whenever'the solenoid 289 is tripped to-c'ause rotation ofs'haft 239 and lifting of bearings 234, the end 294 of latch arm 263 will move to the right-opposite a notch 366 in "the end of 1ever226. Because-ofthe presence of this notch 

